Nitrate Reductase is Needed for Methyl Jasmonate-Mediated Arsenic Toxicity Tolerance of Rice by Modulating the Antioxidant Defense System,Glyoxalase System and Arsenic Sequestration Mechanism

Journal of Plant Growth Regulation - The study was conducted to consider the role of nitrate reductase (NR)-synthesized nitric oxide (NO) in the methyl jasmonate (MJ)-induced tolerance of arsenic...     

Genetic effects of acridine compounds.

Acridines and a very large number of acridine derivatives are used in enormous quantities both in medicine and industry. The mutagenic action of these compounds has been demonstrated in a wide variety of organisms and is known to occur both in the dark as well as in the presence of light (photodynamic action). At the molecular level, acridines have been shown to cause frameshift mutations of both the addition and deletion types, a characteristic which has been of tremendous help in elucidating the nature of the genetic code. These and various other biological effects of acridines, such as inhibition of DNA repair, curing of plasmids and cell-growth inhibition, are examined in this review.     

Contribution of a caffeine-sensitive recombinational repair pathway to survival and mutagenesis in UV-irradiated Schizosaccharomyces pombe

Summary Cells of wild-type Schizosacharomyces pombe exposed to UV radiation in either G1 or G2 phase show enhanced inactivation of colony-forming ability if plated in the presence of caffeine. This UV-sensitization by caffeine is abolished in both G1 and G2 phase cells by the rad1 mutation; since both caffeine and the rad1 mutation markedly reduce recombinational events, this suggests that a recombinational repair process is active in cells irradiated either in G1 or G2 phase. A prereplicative or sister chromatid exchange recombinational process appears to account for caffeine-sensitive repair of UV-damage in G2 cells (which possess at the time of radiation exposure the duplicated genome necessary for recombination), since caffeine-sensitive repair begins immediately and is completed before resumption of DNA synthesis. In contrast, since caffeine-sensitive repair of UV-damage in G1 cells displays a considerable lag and then occurs concomitantly with DNA synthesis, it appears that G1 cells must acquire a second genome in order to accomplish a caffeine-sensitive recovery process. Since a duplicated genome is required for caffeinesensitive repair, all such repair would seem to involve a recombinational mechanism. In G1 cells the process may be a post-replication recombinational mechanism. Since G2 phase cells are considerably more UV-resistant than G1 phase cells, the prereplicative recombinational process appears to be a much more efficient process for dealing with UV-induced damage than the post-replication mechanism.UV-induced mutagenesis was examined in wildtype and rad mutants using a forward mutation system. Rad mutants which show higher UV-induced mutation rates than wild-type retain UV-sensitization by caffeine (and thus presumably retain the recombinational mechanism). In contrast, rad strains which are relatively UV-immutable compared to wild-type do not possess the caffeine-sensitive UV-repair process. The recombinational process therefore may be the major pathway responsible for UV-induced mutation.AECL Reference No. 6251; NRC Publication No. 16999     

UV-induced lethal sectoring and pure mutant clones in yeast

The induction of lethal sectoring and pure mutant clones by ultraviolet light has been studied in a homogeneous G₁ population of Saccharomyces cerevisiae grown in a normal growth medium. At the lowest UV dose of 250 ergs, which corresponds to a shoulder in the survival curve, all mutants appeared as pure clones. At higher doses the frequency of mosaic mutants progressively increased. These results indicate a relationship between the highest frequency of complete mutants and the maximum repair activity. In addition, the frequency of lethal sectoring at all doses tested was too low to account for the origin of pure mutant clones.     

A novel procedure for the recovery of hybrid products from protoplast fusion

Summary A protoplast mixture of two -mating type strains of Saccharomyces cerevisiae was encapsulated in a beaded form of calcium alginate gel. Part of the same protoplast mixture was embedded in a molten (50–55°C) agar overlay, a routine procedure for the recovery of regenerated colonies and hybrid products. The number of hybrid products isolated from the encapsulated protoplast mixtures was greater than that recovered from the agar overlay. The increase ranged from 40 to 1000 fold.     

Role of Ni-tolerant Bacillus spp. and Althea rosea L. in the phytoremediation of Ni-contaminated soils

In our current study, four nickel-tolerant (Ni-tolerant) bacterial species viz, Bacillus thuringiensis 002, Bacillus fortis 162, Bacillus subtilis 174, and Bacillus farraginis 354, were screened using Ni-contaminated media. The screened microbes exhibited positive results for synthesis of indole acetic acid (IAA), siderophore production, and phosphate solubilization. The effects of these screened microbes on Ni mobility in the soil, root elongation, plant biomass, and Ni uptake in Althea rosea plants grown in Ni-contaminated soil (200 mg Ni kg^?1) were evaluated. Significantly higher value for water-extractable Ni (38 mg kg^?1) was observed in case of Ni-amended soils inoculated with B. subtilis 174. Similarly, B. thuringiensis 002, B. fortis 162, and B. subtilis 174 significantly enhanced growth and Ni uptake in A. rosea. The Ni uptake in the shoots and roots of B. subtilis 174-inoculated plants enhanced up to 1.7 and 1.6-fold, respectively, as compared to that in the un-inoculated control. Bacterial inoculation also significantly improved the root and shoot biomass of treated plants. The current study presents a novel approach for bacteria-assisted phytoremediation of Ni-contaminated areas.     

Enhancement of the antiangiogenic activity of interleukin-12 by peptide targeted delivery of the cytokine to alphavbeta3 integrin

We engineered a fusion protein, mrIL-12vp [mouse recombinant interleukin (IL)-12 linked to vascular peptide], linking the vascular homing peptide CDCRGDCFC (RGD-4C), a ligand for alphavbeta3 integrin, to mrIL-12 to target IL-12 directly to tumor neovasculature. The fusion protein stimulated IFN-gamma production in vitro and in vivo, indicating its biological activity was consistent with mrIL-12. Immunofluorescence techniques showed mrIL-12vp specifically bound to alphavbeta3 integrin-positive cells but not to alphavbeta3 integrin-negative cells. In corneal angiogenesis assays using BALB/c mice treated with either 0.5 microg/mouse/d of mrIL-12vp or mrIL-12 delivered by subcutaneous continuous infusion, mrIL-12vp inhibited corneal neovascularization by 67% compared with only a slight reduction (13%) in angiogenesis in the mrIL-12-treated animals (P = 0.008). IL-12 receptor knockout mice given mrIL-12vp showed a marked decrease in the area of corneal neovascularization compared with mice treated with mrIL-12. These results indicate that mrIL-12vp inhibits angiogenesis through IL-12-dependent and IL-12-independent mechanisms, and its augmented antiangiogenic activity may be due to suppression of endothelial cell signaling pathways by the RGD-4C portion of the fusion protein. Mice injected with NXS2 neuroblastoma cells and treated with mrIL-12vp showed significant suppression of tumor growth compared with mice treated with mrIL-12 (P = 0.03). Mice did not show signs of IL-12 toxicity when treated with mrIL-12vp, although hepatic necrosis was present in mrIL-12-treated mice. Localization of IL-12 to neovasculature significantly enhances the antiangiogenic effect, augments antitumor activity, and decreases toxicity of IL-12, offering a promising strategy for expanding development of IL-12 for treatment of cancer patients.     

Evaluating the role of autologous mesenchymal stem cell seeded on decellularized pericardium in the treatment of myocardial infarction: an animal study

Inappropriate left ventricular remodeling following myocardial infarction (MI) can result in subsequent severe dysfunction. In this study, we tested the hypothesis that decellularized pericardium (DP) or seeded pericardial patch with autologous adipose-derived mesenchymal stem cells (ADMSCs) could be safely used in a MI scar and could improve heart function. Twelve rabbits were randomly divided into three equal groups. Four weeks after MI induction by ligation of the left anterior descending artery in 12 rabbits, animals of G1 (n = 4) received DP patch with labeled ADMSCs. DP patch was implanted in animals of G2 (n = 4). Rabbits of G3 (n = 4) remained without any intervention after MI induction (control group). Serial examinations including echocardiography, electrocardiography (ECG), scanning electron microscopy, histology and immunohistochemistry (IHC) were performed to evaluate the efficacy of the implanted scaffolds on recovery of the infracted myocardium. The results demonstrated that left ventricular contractile function and myocardial pathological changes were significantly improved in rabbits implanted with either DP or ADMSC-seeded pericardium. However, the seeded pericardium was more effective in scar repairing 2 months after the operation, IHC staining with Desmin and CD34 and positive immunofluorescence staining verified the differentiation of ADMSCs to functional cardiomyocytes. This approach may involve the application of autologous ADMSCs seeded on pericardial patch in an attempt to regenerate a contractible myocardium in an animal model of MI.